WO2013159009A1 - Glasses for the correction of chromatic and thermal optical aberrations for lenses transmitting in the near, mid, and far-infrared sprectrums - Google Patents

Abstract

The invention relates to chalcogenide glass compositions for use in a lens system to balance thermal effects and chromatic effects and thereby provide an achromatic and a thermal optical element that efficiently maintains achromatic performance across a broad temperature range. The glass composition is based on sulfur compounded with germanium, arsenic and/or gallium, and may further comprise halides of, for example, silver, zinc, or alkali metals. Alternatively, the glass composition is based on selenium compounded with gallium, and preferably germanium, and contains chlorides and/or bromides of, for example, zinc, lead or alkali metals.

Description

GLASSES FOR CORRECTION OF CHROMATIC AND THEREMAL OPTICAL ABERATIONS FOR _,LENSi .TRANSMITTING IN THE

NEAIL Mm AND F AR- ^ERAK I) SPRE CTRUMS

Summary of the Invention

[0001] The invention relates to glass compositions that can be used for manufacturing optical lens that correct for optical aberrations, particularly chromatic aberrations and aberrations due to thermal effects, of lens that transmit light in the near-, mid- and/or far- range infrared spectrum, and preferably also within at least a portion of the visible spectrum,

[0002J infrared [ens transmit light in near-infrared range (e.g., 700nm to 1.8 urn), the mid-infrared range (e.g., 3.0-5.0 um) and/or the far-infrared range (e.g., 8.0-13.0 μτη). Often IR lenses are characterized as transmitting light in the SWIR, MWIR, or LWIR regions, i.e., the short-wave (SWIR) region (wavelengths of 1-3 μηι), mid-wave (MWIR) region (wavelengths of 3-5 μτη). and the long-wave (LWIR) region (wavelengths of 8-12 μτη). Infrared lens are used in a wide variety of applications including low-light level (night vision) imagers such as night vision goggles, thermal imagers, and systems capable of seeing through obscurants such as fog, smoke and dust.

[0003] Night vision devices such as night vision goggles generally rely on low-level reflected light in the visible and near-infrared range. These devices utilize image enhancers that collect the visible and infrared light passing through the lens and amplify the light to produce a visible image, in general, night vision goggles comprise an infrared objective lens which transmits light in the visible and near-infrared range, an image enhancer or intensifier that amplifies the photons and converts them to electrons, and a phosphor or fluorescent display that receives the electrons and produces an amplified image, See, for example, Filipovich (US 4,653,879).

[0004] Thermal imagers utilize emitted, rather than reflected, infrared light, specifically emitted thermal energy. Therefore, thermal imagers generally operate in the mid-infrared s and/or the far-infrared ranges. Humans, animals, and operating machines, for example, produce their own heat which is emitted as infrared radiation. Other objects rocks and buildings absorb heat from the sun, for example, and then radiate that heat as infrared light, Thus, thermal imagers have many civilian and military applications for purposes of surveillance, security and safety, such as imaging people and vehicles, determining hot. spots, and monitoring industrial machinery and processing plants.

[0005] in general, an infrared or thermal imaging system comprises optics including an I lens for collecting and focusing transmitted infrared light and a plurality of thermal sensors for detecting the infrared light and converting it into electrical signals, and a signal-processing unit for converting the electrical signals into a visual image. See, for example, Izumi (US 7,835,071).

[0006] Optical lens including infrared lens are susceptible to several optical aberrations. For example, most imaging systems need to bring light of many wavelengths to a focus at the same distance from the lens. However, the refractive index of all known materials vari es as a function of the wavelength. This variation in refractive index, known as dispersion, produces an aberration known as chromatic aberration, sometimes referred to as "color fringing."

[0007] There are two types of chromatic aberration. Longitudinal chromatic aberration or axial chromatic aberration results when the different wavelengths transmitted by the lens have different focal lengths, since the focal length of a lens varies as a function of its refractive index. As a result, the wavelengths do not focus on the same focal plane. So, for example, the focal distance of blue light will be shorter than the focal distance for red light.

[0008] Lateral chromatic aberration occurs when the different wavelengths are magnified differently by the lens. As a result, the wavelengths will focus at different positions along the same focal plane. [0009] One approach to overcoming chromatic aberration is to use multiple lenses to counter-act the influence of refractive index dispersion on the image. An achromat lens or acliromatic doublet is made by combining two different lens materials that have different dispersion properties. The achromat lens functions to bring two different wavelengths both into focus on the same focal plane, thereby reducing chromatic aberration. [0010] Apochromatic lenses involve multiple materials and are designed to bring three or more wavelengths into focus in the same plane. Such lenses provide belter correction of chromatic aberration and also alleviate spherical aberration (i.e., an aberration thai occurs when light, passing through a lens is refracted more at the lens's edge than at its center). Thus, the use of such doublet or triplet (or greater) lenses may alleviate the phenomeno of chromatic aberration and thereby improve color rendering of an optical system.

[0011] For lenses thai transmit primarily in visible spectrum, the use of doublet or triplet lenses is common practice. One can select two, or in many cases three or even more, materials from a wide range of available glass types, and tune the lens design to the desired optical performance. However, the design of such multiple lens arrangements is more difficult for infrared lenses. The number of optical materials that are transparent in the mid- and far-infrared range is very limited. Such design is even more complicated when transparency in the visible (400nm to 800nm) or near-infrared (700nm to 1 ,8 μτπ) is required simultaneously with and mid-infrared (3,0-5,0 pm) and/or far-infrared (8,0-13.0 μτη) transmission.

{0012] In addition to dispersion, most infrared-transparent materials suffer from a large temperature dependence of the refractive index and from large coefficients of thermal expansion. Both of these factors induce changes in the focal length of a lens as the temperature changes, leading to thermal defocusing. Thus, in addition to addressing the problem of chromatic aberration by providing achromatic infrared lens systems, it is also desirable to provide aihermal infrared lens systems in which the optical performance is stabilized with respect to variations in temperature.

[0013] For a description of prior art attempt to achieve athermalization of IR lens systems, see, for example, Jamieson, T. IT, Athermalization of Optical instruments from the Optomechanical Viewpoint, Proc. SPIE, CR.43, 131 (1992).

[0014] In addition, Arrioia (US 5,737,120) discloses an achromatic and athermal two element objective lens that transmits in the long wave infrared (LWIR) spectral region (8- 12 am). One lens element of the objective lens is made of zinc selenide (ZnSe) and has a positive optical power. The other lens element is made of germanium (Ge) and has a negative optical power. The positive lens element has a lower thermo-optic coefficient (lower dn/dT) than the negative lens. This difference in thermo-optic coefficient provides for athermaiization of the lens system, but not color correction. To provide color correction, Arriola attaches a diffractive optical surface on one surface of either lens element. OOJS] From an optical perspective, the halides (F, C!, Br and Ϊ) of silver (Ag), thallium (Tl). and the alkali metals ( a, , Rb and Cs) are attractive materials for attempting to fulfill the requirements of an achromatic and athermal compound IR lens. However, these materials suffer from extremely low mechanical durability, high toxicity, and. in the case of the alkali metals, extreme sensitivity to moisture. Therefore, the use of these materials is commonly seen as impractical

[0016] Other polycrystalline materials that could possibly satisfy the desired criteria include polycrystalline compounds of alkaline earth elements (Ca, Sr, Ba) with fluorine and compounds of zinc (Zn) with group IV "chalcogenide" elements (S, Se). These materials are known to have sufficient chemical and mechanical durability. However, the combination of their particular refractive indices and dispersions are not suitable for practical achromatic optics. Moreover, the fluorides tend to lack sufficient transmission at wavelengths beyond 10 μτη. Intrinsic semiconductor materials composed of Group IV elements (Si and Ge) or compounds of group III and group V elements such as GaAs and InSb do not simultaneously offer sufficient mid/far-IR. and visible/near-IR transparency.

[0017] Since the chemical composition of crystalline compounds is fixed, it is not possible to tune their properties to allow achromatic performance in a two-element lens system through varying the composition. On the other hand, glasses which offer both infrared and visible transparency might, by compositional tailoring, be used to balance the chromatic effects of other glasses or crystalline materials in a compound IR lens. However, to date no glasses are available that have properties tuned to satisfy the requirements of achromatic and athermal optical element for broadband optics. It Is possible to achieve achromatic and athermal performance using a large number of crystalline compounds, often using greater than 5 individual optical elements. But, such designs are costly due to added mechanical complexity and the need for many specially designed anti-reflection coatings, or such designs have poor performance due to large reflection losses at the various interfaces. Additionally, most of the available crystalline materials, such as Br or KRS5 (thallium bromo-iodide; TIBr-TlI) suffer poor mechanical and chemical stability and may be highly toxic.

{0018] Therefore, an aspect of the in vention is to provide glass compositions, in particular chalcogenide glass compositions, for use in a lens system that simultaneously balances both the thermal effects and chromatic effects of multiple lenses within a compound optical element to achieve an infrared optical system that will efficiently maintain achromatic performance across a broad temperature range, and preferably is suitable for use in broadband optics.

[0019] Upon further study of the specification and appended claims, further aspects and advantages of this in vention will, become apparent to those skilled in the art.

[0020] According to one aspect of the in venti on, there is provided a glass composition based on sulfur compounded with germanium, arsenic and/or gallium that may further comprise haiides of silver, copper (Cu⁺¹), cadmium, zinc, lead (Pb⁺²), alkali metals, alkaline earth metals, or rare earth metals, wherein the glass composition transmits near-, mid-, and/or far-infrared light. The glass system based on sulfur compounded with germanium, arsenic and/or gallium provides compositions with relatively low refractive indices. Moreover, these glass compositions exhibit relatively low refractive index dispersion in the mid-infrared range, although the refractive index dispersion in the near- and far-infrared can be high. The optional haiides provide the ability to not only enhance infrared transparency of the glass, but also aid in controlling refractive index dispersion and thermal expansion.

|0021] According to a further aspect of the invention, there is provided a chalcogenide glass composition based on sulfur compounded with germanium, arsenic and/or gallium, comprising (based on mo I %):

As 0-40,0

Ge 0-35.00

0-7.25

(added in the form of R Hal)

R^{^} 0-13.5

(added in the form of RT ) M¹ 0-5

(added in the form of M³ Hal₂) 2 0-7.25

(added in the form of M Hal₂) Ln

(added in the form of Lnl !«!_.·}

Sum of Ga₅ As, and Ge 10.00-42.00

Sum of R ^!„ RA M^] . M², and Ln 046.00

Sum of Hal 0-16.00

wherein

Hat = fluoride, chloride, bromide, and/or iodide.

R¹ Li, Na, K, R.h, and/or Cs,

R^{2 :::} As, and/or Cu,

M^{1 ::::} g, Ca, Sr, and/or Ba,

^: Zn, Cd, Hg, and/or

Ln ^:::: La, Ce, Pr, Nd, Pm, Srn Eu, Gd, Tb, Dy, Ho, E.r, Tm, Ty, Lu, Y, and

Sc; and wherein a portion of the gallium can be replaced by indium, and a portion of the arsenic can be replaced by antimony. ] The glass system based, on sulfur compoimded with germanium, arsenic and/or gallium, at a thickness of 10mm, preferably transmits at least 75% of incident light at wavelengths from 500 nm to 1 1000 ran, especially at least 70% of incident at

wavelengths from 650 nm to 12000nm, and particularly at least 70% of incident at wavelengths from 500nm MGOOnm.

[0023] The glass system based on sulfur compounded with germanium, arsenic and/or gallium also preferably exhibits an extinction coefficient of < 0.1 em^"1 at wavelengths from 500 nm to 1 1000 nm, especially at wavelengths from 650 nm to 12000nm, and particularly at wavelengths from 500nm MQQOnm.

[0024] According to another aspect of the invention, there is provided a glass

composition based on selenium compounded with gallium, and containing a large of chlorides and/or bromides of silver, copper (Cu^+f ), cadmium, zinc, mercury, lead (Pb⁺²), alkali metals, alkaline earth metals, or rare earth metals, wherein the glass composition transmits near-, mid-, and/or far-infrared light.. These glasses offer enhanced infrared transmission, and lower far- infrared dispersion, but require significantly higher additions of halides to achieve high visible transmission.

[0025] According to a further aspect of the invention, there is provided a chalcogenide glass composition based on selenium compounded with gallium and optionally germanium, comprising (based on mol %):

Se 30.00-68.00

Ga 5.00-30.00

Ge 0-25.00

R¹ 0-25.00

(added in the form of

R ^! S !ai ' )

R² 0-25.00

(added in the form of

R²IIaT^!) M 0-12.50

in the form of

M^;Hal 2)

0-20.00

(added in the form of

M^'Hal¹?)

Ln. 0-8.00

(added in the form of

LnHal's)

Sum of Se, Ga, and Ge 50.00-93.33

Simi of R^ R M^ M², and 1.67-25.00

Ln

Sum of Hal 5.00-25.00 wherein

Hal = chloride and/or bromide. R¹ = Li, Na, K, Rb₅ and/or Cs, R² = Ag and/or Cu, M¹ Mg, Ca, Sr, and/or Ba, M^{2 ::::} Z.n, Cd, Hg, and/or Pb,

Ln La, Ce, Pr, d, Pm, Sra Eu, Gd, Tb, Dy, Ho, Er, Tm, Ty, Ln, Y, and

Sc; and wherein a portion of the gallium can be replaced by indium.

[0026] The glass system based on selenium compounded with gallium, and containing a chlorides and/or bromides, at a thickness of 10mm, preferably transmits at least 75% of incident light at wavelengths frora 500 nni. to 11000 nm, especially at least 70% of incident at wavelengths from 650 nm to 12Q00nm, and particularly at least 70% of incident at wavelengths from 500nm MOOOrim.

[0027] The glass system based on selenium compounded with gallium, and containing a chlorides and/or bromides also preferably exhibits an extinction coefficient of < 0,1 cm^" at wavelengths from 500 nm to 1 1000 nm, especially at wavelengths from 650 nm to 120G0nm, and particularly at wavelengths from 500nm 1400Gnm. [0028] For both the sulfur based compositions and the selenium based compositions, the properties of most interest, in addition to good chemical and mechanical durability and desired light transmission, are index dispersion, coefficient of thermal expansion, find thermal dependency of refractive index.

[0029] The index dispersion is preferably as low as possible. The amount of index dispersion is measured as the Abbe number in the visible, ¥_a\ which is calculated as V_ci - (¾-l)/(n_F-nc) where ?¾, n_? and nc are the refractive indices of th material at the d line, F line, and C line (F line: 486.13 nm, d Line: 587.56 nm, C line: 656.27 nm). Abbe number in the mid-IR range (3-5 μτη) is generally calculated using the index at 3000, 4000, and SOOOmii while the Abbe number in the long-wave range (8-1.2 μη ) may be calculated using the index at 8000, 10,000 and 12,0Q0nm.

[0030] In general, the higher the Abbe No. the lower index dispersion, The glass compositions according to the invention preferably exhibit an Abbe No. in the visible range of at least 1.5, for example, 20 -· 30, especially greater than 25. In the mid-infrared range the glasses preferably exhibit an Abbe No. of at least 100, for example, 100 - 300, especially at least 1 80, particularly greater than 200. In the far-infrared range the glasses preferably exhibit an Abbe No. of at least 60, for example, 60-1 85, especially at least 100, particularly greater than 120.

[0031] Similarly, the coeffici ent of thermal expansion, a, is preferred to be as low as possible for the glass compositions according to the invention. Thus, the glasses according to the invention preferably have a coefficient of thermal expansion that is less than 50 x 10^"6/ or example, 15 x 1 ίΓ /Κ - 25 x 10^"6 .

[0032] The thermal dependency of the refractive index, measured as dn dT (the temperature coefficient of the refractive index), is also preferably low. Thus, the glasses according to the invention preferably have a dn/dT value of less than 30 x 10^~6/K, for example, 5 x 10^~6/K - 30 x 10^~6/ . [0033] According to an aspect of the invention, there is provided a glass composition based on sulfur compounded with germanium, arsenic and/or gallium, the glass composition comprising (based on mol %):

Mole %

S 58.00-90.00

Ga 0-25.00 As 0-40,0 Ge 0-35,00

0-7.25

(added in the form of R Hal)

R"^'

(added in the form of R²HaI) M¹

(added in the form of M^IHal₂)

M² 0-7.25

(added in the form of M'Halj.)

Ln 0-4.00

(added in the form of LnHals)

Sum of Ga, As, and Ge 10.00-42.00

Sum of

M², frnd Ln 0-16.00

Sum of Hal 046.00

wherein

Hal ^:::: fluoride, chloride, bromide, and/or iodide,

R¹ = Li, Na, K, Rb, and/or Cs,

R" = Ag and/or Cu,

M^! = Mg. Ca, Sr, and/or Ba,

M ^::: Zn, Cd, Hg, and/or Pb, Ln = La, Ce, Pr, Nd, Pm, Sm Eu, Gd, Tb, Dy, Ho, Er, Tm, Ty, Lu, Y, and Sc,

According to a further aspect, the invention includes a glass composition, based on sulfur compounded with germanium, arsenic and/or gallium, comprising (based on mol %):

0-5

(added in the form of

R¾al)

R 0-10

(added in the form of

R'Hal)

0-3

(added in the form of

M^-la ) hi: 0-5

(added in the form of

(added in the form of

LnHal₃)

Sum of Ga, As, and Ge 30,00-40.00

Sum of R¹ , R², M³ , M², 0- 10

and Ln

Sum of Hal 0-10

[0035] According to another aspect of the invention, there is provided a glass composition based on selenium compounded with gallium, the glass composition comprising (based on mol %):

Se 30.00-68.00 Ga 5.00-30,00 Ge 0-25.00 R¹ 0-25.00

(added in the form of

R Hal¹)

R² 0-25.00

(added in the form of

R¾al⁵)

M¹ 0-12.50

(added in the form of

M'Hal^)

0-20.00

(added in the form of

Ln 0-8

(added in. the form of

LnHal^! )

Sum of Se, Ga, and Ge 50.00-93.33

Sum. of R¹, R²,

M², and 1.67-25.00

Ln

Sum of Hal¹ 5.00-25.00 wherein

Hal^! = chloride and/or bromide,

R⁵ = Li. Na, K, Rb, and/or Cs.

R" = Ag and/or Cu,

M^{3 :}- Mg, Ca, Sr, and/or Ba, 3VT = Zn, Cd_s Hg, and/or Pb, and

Ln = La, Ce, Pr. Nd, Fm, S Eu, Gd, Tb, Dy, Ho, Er, Tm, Ty, Lu, Y, and Sc.

[0036] According to a further aspect, there is provided a glass composition, based on selenium compounded wiih gallium, comprising (based on mo! %):

Mole % 35.00-65.00 7.00-22.00

18.00-23.00

0-20

(added in die form of

R¹Hal¹)

(added in the form of M¹

(added in the form of

T i lai

0-15.00

(added in the form of

Ln

(added in the form of

LnHai⁵ ₃)

Sum of Se, Ga, and Ge 55.00-85.00

Sum of R¹, R², M M², and ] .67-22.00

Ln

Sum of Hal¹ 7.5-22.00

[0037] With regards to the sulfur based compositions, tbe amount of sulfur is 58.00- 90.00 mol %, preferably 58.00-75.00 mol%, based on the total moles (e.g., based on total moles of S, Ga, As, Ge, R , R", M^', M , Ln and Mai when neither In nor Sb are present). According to another aspect, the sulfur based glass compositions according to the invention contain 65.00-75,00 mol% of sulfur, for example, 60.00 - 65.00 mol% of sulfur, or 70.00 - 75.00 mol% sulfur, or 65.00 - 70.00 raol% sulfur. [0038] Also, in the sulfur based compositions the amount of gallium is 0-25.00 mol %, based on the total moles (e.g., based on total moles of S, Ga, As, Ge, R , R , M¹, I f, Ln and Hal), According to another aspect, the sulfur based glass compositions according to the invention contains 0-20.00 mol% Ga, for example, 0-10.00 mol% Ga, 5.00 - 15.00 mol% Ga, or 5.00 - 10.00 mol% Ga, or 6 mol%, 7 mol%, 8 mol%, or 9 mol%. [0039] According to another aspect, in the sulfur based glass compositions according to the invention a portion of the gallium can be replaced by indium, particularly in situations were a lower amount of visible transmission is acceptable. The presence of In tends to reduce visible transmission. However, the combined total amount of gallium and indium is still preferably 0-25 mol%, based on the total moles (e.g., based on total moles of S, Ga, In, As, Ge, R^!, R², M¹, M², Ln and Hal). For example, the sulfur based glass compositions according to the invention can contain 0-5 mol % In and 20-25 mol % Ga, or 0-12 mol % In and 0-12 mol % Ga, or 20-25 mol % In and 0-5 mol % Ga.

[Θ040] In the sulfur based compositions the amount of arsenic is 0-40.00 mol %, based on the total moles (e.g., based on total moles of S, Ga, As, Ge, R^l, R², M¹, Ivf¹, Ln and Hal). According to another aspect, the sulfur based glass compositions according to the invention contain, for example, 0-10.00 mol% As, or 10.00 - 25,00 mol% As. or 25,00 - 35.00 mol% As, or 35.00 - 40.00 mol% As.

[0041] According to another aspect, in the sulfur based glass compositions according to the in vention a portion of the arsenic can be replaced by antimony, particularly in situations were a lower amount of visible transmission is acceptable, The presence of Sb tends to reduce visible transmission. However, the combined total amount of arsenic and antimony is still preferably 0-40.00 mol%, based on the total moles (e.g., based on total moles of S, Ga, As, Sb, Ge, R , R% M\ , Ln and Hal). For example, the sulfur based glass compositions according to the invention can contain 0-10 mol % Sb and 0-30 mol % As, or 0-20mol % Sb and 0-20 mol % As, or 0-30 mol % Sb and 0-10 mol % As, [0042] in the sulfur based compositions the amount of germanium is 0-35.00 mol %, based on the total moles (e.g., based on total moles of S, Ga, As, Ge, R.\ R\ M¹, W, Ln and Hal), According to another aspect, the sulfur based glass compositions according to the invention contain 0-25.00 mo!% Ge, for example, 5.00 - 25,00 mol% Ge. or 10.00 - 20.00 mol% Ge, or 20.00 - 25 ,00 mol% Ge.

[0043] In the sulfur based compositions the total combined amount of Ga, As, and Ge is 10.00-42,00 mol %, based on the total moles (e.g., based on total moles of S, Ga, As, Ge, R^l, R², M¹, M², Ln and Hal). According to another aspect, the sulfur based glass compositions according to the invention contain, for example, a total combined amount of Ga, As, and Ge of 20.00-40.00 mol%. or 25.00 - 40,00 mol%, or 30.00 - 40.00 mol%,

[0Θ44] in the sulfur based compositions the amount of Hal is 0-13,5 mol %, based on the total moles (e.g., based on total moles of S, Ga, As, Ge, R¹, R^, M¹, M , Ln and Hal). According to another aspect, the sulfur based glass compositions according to the invention contain 0-10.00 mol% Hal for example, 1.00 - 10.00 mol% Hal, or 2.00 - 9.00 mol% Hal, or 3.00 - 5.00 mol% Hal.

[004S] The selection of halide compounds can affect the critical cooling rate of the glass composition, In general, the halides M Hal₂ (M² = Zn, Cd, or Pb) and R²Hal (R^{2 :::} Ag or Cu) produce glass at lower cooling rates and are, therefore, preferred, while glass made with the halides R⁵Hai (R³ = Li, Na, K, Rb, or Cs) and M³Hal₂ (M⁵ = Mg, Ca, Sr, or Ba) tend to requires more rapid cooling. At a given cooling rate, a higher total halogen content may be achieved using M²Hal₂ and R Hal halides, as compared to R^JHal and M^JHal₂.

[0046] The addition of chlorine is most efficacious in modifying the visible transmission and thereby the short- wavelength dispersion, which are liked though the Kramers-Kronig relation. The addition of Br has a somewhat larger effect than CI on increasing thermal expansion and thereby reducing dn/d^'T which is linked through the Lorenz-Loreniz relation. Br also has a slightly impact on increasing IR transmission but a lower impact on increasing visible/NIR transmission relative to CI. The identity of the alkali elements is also impacts thermal expansion. Larger alkali ions (Cs) will generally tend to increase thermal expansion compared to smaller ions (Li), On the other hand, the identity of the alkali element will have very little effect on the transmission or dispersion,

[0047] With regards to the selenium based compositions, the amount of selenium is 30,00-68,00 moi %, based on the total moles (e.g., based on total moles of Se, Ga, Ge, R¹, R², M M², Ln, and Hal¹ or the total moles of Se, Ga, In, Ge, R\ R², M³, M², Ln, and Hal¹). According to another aspect, the selenium based glass compositions according to the invention contain 30.00-65.00 mol% of selenium, for example. 30.00 - 60.00 mol of selenium, or 30.00 - 55,00 mol% selenium, or 30,00 - 40.00 mo!% selenium, or 40.00 -- 55,00 moi.% selenium,

[0Θ48] In the selenium based compositions the amount of germanium is 0-25.00 mol , based on the total moles (e.g., based, on total moles of Se, Ga. Ge, R¹, R², M¹, M , Ln, and Hal), According to another aspect, the selenium based glass compositions according to the invention contain 15-25.00 mol% Ge, for example, 15.00 - 20.00 mol% Ge, or 20,00 - 25.00 mol% Ge, or 19,00 - 23.00 mo.1% Ge. it should be noted that the presence of germanium in the selenium based compositions is preferred as it tends to prevent phase separation. If germanium is not present, then it is desirable to use high amounts, e.g., of ehlorides/¾romides to prevent phase separation. [0049] Also, in the selenium based compositions the amount of gallium is 5-30.00 mol %, based on the total moles (e.g., based on total moles of Se, Ga, Ge, R , R", M , M", Ln, and Hal). According to another aspect, the sulfur based glass compositions according to the invention contains 5-22.00 mol% Ga for example, 5-20.00 mol% Ga, 5.00 - 15,00 mol% Ga, or 5.00 - 10.00 mol% Ga, or 6 mol%. 7 mol%, 8 mol%, or 9 mol%.

[0050] According to another aspect, in the selenium based glass compositions according to the invention a portion of the gallium can be replaced by indium, particularly in situations were a lower amount of visible transmission is acceptable, The presence of In tends to reduce visible transmission. Ho wever, the combined total amount of Gallium and Indium is still preferably 5-30.00 moi%, based on the total moles of Se, Ga, In, Ge, R¹, R², i¹, M², Ln, and Hal¹. For example, the sulfur based glass compositions according to the invention can contain 0-10 mol % In and 20-30 mol % Ga, or 5-15 mol % In and 5-15 mol % Ga, or 20-30 mol % In and 0-10 mol % Ga,

[0051] In die seleni um based compositions the total combined amount of Ga and Ge is preferably 20,00-40.00 mol %, based on the total moles of based on the total moles of Se, Ga, Ge, R^l, R², M¹, M², Ln, and. Hal⁵. According to another aspect, the sulfur based glass compositions according to the Inventi n contain, for example, a total combined amount of Ga, As, and Ge of 21.00-40.00 moI%, or 25.00 - 35.00 mol%, or 25.00 - 30.00 mol%.

[0052] In the selenium based compositions the amount of Hal¹ is 5-25 mol %, based on the total moles of Se, Ga, In, Ge, R¹, R², M^!, M², Ln, and Hal¹. According to another aspect, the sulfur based glass compositions according to the invention contain 5-15.00 mol% Hal¹, for example, 5.00 - 10.00 mol.% Hal¹, or 6.00 -- 9.00 moi% Hal¹, or 7.00 - 9.00 mol% Hal¹. [0053] As noted above, the selectio of halide compounds can affect the cooling rate of the glass composition. In general, the halides M²Hal₂ (M² = Zn, Cd, Hg, or Pb) and R²Hal (R² = Ag or Cu) produce glass at lower cooling rates and are, therefore, preferred, while glass made with the halides R1Hal (R¹ = Li, Na, K, Rb, or Cs) and M^lHal₂ (M³ = Mg, Ca, Sr, or Ba) tend to requires more rapid cooling. At a given cooling rate, a higher total halogen content may be achieved using fvT^'] iaL and R/^'Hal halides, as compared to R¹Hal and ^lHal₂.

[0054] As mentioned above, the addition of chlorine is most efficacious in modifying the visible transmission and thereby the short wavelength dispersion, which are liked though the Kramers-Kronig relation. The addition of Br has a somewhat larger effect on increasing thermal expansion and thereby dn/dT which are linked through the Lorenz- Lorentz relation, Br also has a slightly higher impact on increasing transmission but. its impact on visible transmission is weaker as compared to CI. The identity of the alkali elements is also impacts thermal expansion, Larger alkali ions (Cs) will generally tend to increase thermal expansion compared to smaller ions (Li). On the other hand, the identity of the alkali element will ha ve very little effect on the transmission or dispersion, However, Cs is preferred over Na or K when large amount of Hal are desired. [00551 According to a further aspect, in the sulfur based compositions it is can be advantageous for the compositions to further contain selenium. Similarly, in the selenium based compositions it is can be advantageous for the compositions to farther contain sulfur. The combined presence of sulfur and selenium improves the stability of the glass and permits the achievement of optical properties that are between those of the sulfur based compositions and those of the selenium based compositions. For example in either the sulfur based, the ratio of Se/S can be about 0-1.0, and in the selenium based compositions ratio of S/Se can be about 0-1.0.

[0056] According to a further aspeefin both the sulfur based compositions and selenium based compositions, improved stability can be achieved using higher amounts of S or Se relative to Ga. For example, the sum of the amount of S plus the amount of Se is preferably greater than the sum of 2 times the amount of Ge plus 1.5 times the amount of Ga, preferably the amount of S plus the amount of Se is equal to about 2 times the sum amount of Ge plus the amount of Ga.

[0057] According to an additional aspect of the invention, there is provided a

chalcogenide glass composition based on selenium compounded with lead and either germanium, antimony or the combination of germanium and antimony, comprising (based on mol %):

Component Mole %

PbHah 10.00-50.00

GeSe₂ 0-60.00

Sum of GeSe₂ and Sb₂Se3 50.00-90,00

0-15.00

(added in the form of R1HaS)

0-5.00

the form of M^lHal₂) M 0-30.00

(added in the form of IV! -^'Hal 2)

Ln 0-2.00

(added in the form of LnHala) of R¹, R², M¹, M and Ln 0-15.00

(added in the forms of R¹Hai,

R²Hal, M^lHal₂, M²Hal_2> and

LnH& )

wherein

Hal = fluoride, chloride, bromide, and/or iodide (preferably Br and/or I, with a Br/ΐ ratio of 0-0.8),

R¹ = Li, Na, K_s Rb, and/or Cs,

R² = Ag and/or Cu,

M³ Mg, Ca, Sr, and/or Ba.

M² Zn, d, and/or Hg

Ln - La, Ce, Pr, Nd, Pm, Sm Eu, Gd, Tb, Dy, Ho, Er, Tm, Ty, Lu, Y, and

[0058] This chalcogenide glass composition based on selenium compounded with lead system exhibits low dn/d^'T and low dispersion over the S 1R MIR and LWIR spectral ranges (1.0-15 microns) and is more resistant to attack by water, compared to systems that containing alkaline elements.

Brief D scripti ri he Dra ing

[0059] Various other features and attendant advantages of the present invention will be more fully appreciated as the same becomes better understood whe considered in conjunction with the accompanying drawings, in which like reference characters designate the same or similar parts throughout the several views, and wherein; Figure 1 illustrates a doublet lens system containing a corrective lens in accordance with the invention; and

Figure 2 illustrates a triplet lens system containing a corrective lens made from two glasses in accordance with the invention,

[0060] As described, above, optical materials for I wavelengths suffer from thermally- induced changes in focal length in lenses due to thermal expansion and dn/dT. In an achromatic doublet lens, the dispersions combine to provide equal powers at 2

wavelengths. To athennahze a lens (i.e., to reduce thermal effects), the coefficient of thermal expansion (CTE) and dn/dT need to be balanced. Therefore, using the following equations:

I DL dn β

a (CTE) = ^ ( ^^' ) , β = dt _s and δ ^{=:: w -} l - a (thermal change in focal power), one can estimate the requirements for achieving an atherma! and achromatic system.

[0061] For a doublet lens, the power, K, is equal to the powers of the individual lens, i.e., Ki + ¾ = K (doublet). For an achromatic lens, Kj/Vi + K /VI ^:::: 0 (i.e., K₂ ^~ ~K| V2/V 1) V represents the Abbe No. For athermalization, Κχδι + ¾ δ₂ = Κ<¾, where is the thermal expansion coefficient of the housing material (i.e., the housing holding the lens). Combining the equations results in δ₂ ^:::: [Vi(cih- Si j V ] + c¾. Thus, the corrective lens of the doublet preferably satisfies this criterion.

[0062] Figure 1 illustrates a doublet lens wherein an infrared lens 1 is paired with a corrective lens 2 made a clialcogenide glass composition according to the invention. The IR lens I and corrective lens 2 are preferably fused together, although they can also be separated by a small air space. Lens 1 can be made from any of the commonly used material for IR lenses, for example. ZnSe, ZnS, Ge, GaAs, BaF₂, and chalcogenide glasses, preferably ZnSe or ZnS. Preferably, a ZnSe IR lens is paired with a corrective lens made from a selenium based glass composition according to the invention, as these glasses will have similar transmission properties. ^'For similar reasons, a ZnS IR lens is preferably paired with a corrective lens made form a sulfur based glass composition according to the invention. [0063] As shown in Figure L light passing through the 1R lens 1 is subjected to dispersion due to the variance in refractive index, which causes the focal length to be shorter at shorter wavelengths. This light then passes through corrective lens 2 which corrects the light transmission by preferentially increasing the focal length relative to that created by the first lens at shorter wavelengths, thereby counteracting the effects of the first lens.

[0064] Figure 2 illustrates another embodiment according to the invention wherein a pair of lenses may be added to the system in order to leave the focal length at a single wavelength unaffected but. to change either the dispersive or thermal behavior of the system in order to counteract the effects of the main focusing element. This is most efficacious in correcting problems in existing systems. For instance, thermal defocus in Germanium-based optical systems may be corrected by inserting a lens pair with an infinite focal length at room temperature, but which becomes negative at elevated temperatures or positive at. decreased temperatures, thereby correcting the errors introduced by the germanium element.

[0065] Thus, an existing lens may be corrected using two lenses (one positive and one negative) which give a total power of 0 (afocal) at the center wavelength, but which have different V and 6 to correct deficiencies of the primary lens wi thout change overall focal length. Thus, the powers of the two corrective lenses are to cancel each other out, i.e., Ki + K.₂ + ¾ = Ki when K₂ ^::: -¾ {¾ is the power of the existing lens and ₂ and 1¾ are the powers of the doublet lens). Going through the process of achromatizing and

althermalizing using the equations described above, the 2 glasses of the doublet lens preferably satisfy the following (with a preference for small 1¾): [V2V3/V 1CV3-V₂) = (c¾-

10066] Thus, in Figure 2 an infrared lens 1 is used in combination with a doublet lens containing lens elements 2 and lens 3, one having a negative power and the other having a positive power. The negative power lens element should have higher dispersion (smaller V) and higher δ than positive lens element. Lens 2 and lens 3 are preferably fused. Lens 1 can be made from any of the commonly used material for IR lenses, for example, ZnSe, ZnS, Ge, GaAs, BaF₂, and known chalcogenide glasses, preferably ZnSe or ZnS. At least one of lens 2 and lens is made from a chalcogenide glass composition

9 according to the invention. The other lens can be made from a chalcogenide glass composition according to the invention or from any of the commonly used material for IR lenses, such as ZnSe, ZnS, Ge, GaAs. BaF?, and known chalcogenide glasses. For example, lens 1 can be of ZnS, lens 2 can be from a chalcogenide glass composition according to the invention, and lens 3 can be made of ZnSe.

Examples

[0067] The glasses of this invention can be fully conventionally prepared by mixing the appropriate amounts of each constituent to form a batch composition which is then charged into a fused silica ampoule and melted by radiative heating, e.g., from 6G0°C to as much as 1050°C, depending on die chosen composition, typically 2 to 4 hours, again depending on composition and melt viscosity while rocking the melt in order to cause agitation and increase homogeneity. The glass within its ampoule is then typically removed from die furnace and allowed to cool by convection in room temperature air to a temperature near its glass transition temperature. The ampoule and glass sample are then placed into a heated oven at the glass transition temperature plus about 20^CC for about 2 hours followed by cooling at about 30°C/hour. These procedures are followed in the examples below.

[Θ068] As noted above, the examples of this application are melted in a fused silica ampoule. It is well known that chalcogenide compounds, particularly those of S with Ge or Ga possess high vapor pressures near the melt temperature. The pressure evolved during melting may exceed the burst pressure of the silica vessel, leading to rupture of the ampoule. Also, die thermal expansion of these glasses is relatively large compared to that of the ampoule. Under the conditions of wetting of the glass to the interior of the ampoule, the stress induced during quenching may cause a rapture ampoule and/or glass ingot within. The temperatures and heating rates during the melting and quenching operations must therefore be chosen judiciously in order to prevent rupture, depending on the design of the ampoule and dimensions and composition of the glass ingot. The need to control these factors while still providing sufficiently high melting temperatures and cooling rates while quenching combine to limit the dimensions of the ampoule and glass sample which may he prepared.

[0069] Without further elaboration, it is believed that one skilled in the art can, using the preceding description, utilize the present invention to its fullest extent. The following preferred specific embodiments are, therefore, to be construed as merely illustrative, and. not limitative of the remainder of the disclosure in any way whatsoever.

[0070] Tables 1 A, I B, ! C, ID, I E, and I F list examples of the glass composition according to the invention. Tables 1 A - ID list examples of the sulfur based glass composition and Tables IE and IF lists examples of the selenium based glass composition,

Table 1A, Examples of Sulfur Based Glass Compositions (mol%) According to the invention

Table IB. Further Examples of Sulfur Based Glass Compositions (mol%) According to the Invention

Table 1C. Examples of Selenium Based Glass Compositions (mol%) According to the Invention

Table ID. Examples of Selenium Based Glass Compositions (mol%) According to the Invention

ota j

Table IE. Further Examples of Selenium Based Glass Compositions (mol%) According to the Invention

Table IF. Further Examples of Selenium. Based Glass Compositions (mol%) According to the Invention

[0071] The preceding examples can be repeated with similar success by substituting the generically or specifically described reactants and/or operating conditions of this invention for those used in the preceding examples, [0072] From the foregoing description, one skilled in the art can easily ascertain the essential characteristics of this invention and, without departing from the spirit and scope thereof, can make various changes and modifications of the invention to adapt it to various usages and conditions. [0073] The entire disclosurej s] of all applications, patents and publications, cited herein, are incorporated by reference herein.

Claims

Claims

1. A chalcogenide glass composition comprising (based on mol % of total

(a)

Component Mole %

S 58,00-90,00

Ga 0-25,00

As 0-40.0

Ge 0-35,00 5 0-7.25

(added in the form of R. ^! ) !a!)

R² 0-13.5

(added in the form of R'Hal)

(added in the form of M Hal₂)

0-7,25

(added in the form

Ln 0-4

(added in the form of LnHals)

Sum of Ga, As, and Ge 10,00-42.00

Sum of R¹ , R², M^! , M², and Ln 0-16,00

Sum of Hal 0-16.00

wherein

Hal = fluoride, chloride, bromide, and/or iodide, R¹ = Li, Na, K. Rb, and/or Cs.

R ^' = Ag and/or Cu,

M^{1 ::::} Mg, Ca, Sr, and/or Ba, M² = Zn, Cd, Hg, and/or Pb, and

Ln ^:::: La, Ce, Pf, Nd, Pm, Sm Eu, Gd, Tb, Dy, Ho, Er, Tm, Ty, Lu, Y, and

Sc: or

(b)

Component

Se 30.00-68.00

Ga 5.00-30.00

0-25.00

(added in the form of

" lal¹)

M¹ 0-12.50

(added in the form of

M^v!al¹,)

M² 0-20.00

(added in the form of

M¾al^; ₂)

Ln 0-8

(added in the form of

LnHal )

Sum of Se, Ga, and Ge 50.00-93.33

Sum of R\ R\ i¹, M² and 1.67-25.00

Ln

Sum of Hal¹ 5.00-25.00 wherein

Hal^{1 ::::} chloride and/or bromide.

R ^:::: Li, Na, , Rb, and/or Cs,

R² = Ag and/or Cu, M¹ = Mg, Ca, Sr, and/or Ba, M^{2 ::::} Zn, Cd, f ig, and/or Pb, and

Ln = La, Ce, Pr. Nd, Pm, Sm Eu, Gd, Tb, Dy, Ho, Er, Tm, Ty, Lu, Y, and

Sc; and wherein in each of (a) and (b) a portion of the gallium can be replaced by indium, and wherein in (a) a portion of the arsenic can be replaced by antimony,

2. A chalcogenide glass composition according to claim 1, wherein said composition comprises (based on mol %):

Component Mole %

S 58.00-90,00

Ga 0-25.00

As 0-40.0

G-6 0-35.00

R^l 0-7.25

(added in the form of R¹ Hal)

R² 0-13.5

(added in the form of R"Hal)

M¹ 0-5

(added in the form of M^!H l )

M² 0-7.25

(added in die form of ΜΉκ1?.)

Ln 0-4

(added in the form of LnHalj)

Sum of Ga, As, and Ge 10.00-42,00

S urn of R¹, R², M^] , M², and Ln 0- 16.00

Sum of Hal 0-16,00 3, A chalcogenide glass composiiion according to claim 1, wherein said composition comprises (based on mol %):

Component Mole %

Se 30,00-68,00 Ga 5.00-30.00 Ge 0-25.00 R< 0-25.00

(added in the form of

R^Hal⁵)

0-25.00

0-12.50

(added in the form of

M^!Hal^¾ ₂)

0-20.00

form of

Ln 0-8

(added in the form of

LnHaFs)

Sum of Se, Ga, and Ge 50.00-93.33

Sum of R^¾ , R², M¹, M², and 1 ,67-25.00

Ln

Sum of Hal¹ 5.00-25.00

4. A chalcogenide glass composition according to claim 2, wherein said composiiion comprises (based on mol %);

Component Mole %

S 65,00-75.00

Ga 0-10.00

As 0-35.00 Gc -30.00

R¹ 0-5

(added in the form of

R1Hal)

R 0-10

(added in the form of

^Hal)

M¹ 0-3

(added in the form of

M1Hal₂)

(added in the form of

M²Hal₂)

Ln

(added in the form of

LnHals)

Sum of Ga, As, and Ge 30.00-40.00

Sum of R^ R^ M^ M² 0-10

and Ln

Sum of Hal 0-10

5. A chalcogenide glass composition according to claim 3, wherein said composition comprises (based on mol %):

Component Mole %

Se 35.00-65.00

Ga 7.00-22.00

Ge 18.00-23.00

0-20

(added in the form of

R'Hal¹)

0-20.00

(added in the form of

R²Ha!^!) M¹

(added in the form of

M lal^)

0-15.00

(added in the form of

0-5

(added in the form of

LnHal³ ₃)

Sum of Se, Ga, and Ge 55,00-85.00

Sum of R ¹ , R², ^l , ² and 1.67-22.00

Ln

Sam of Hal⁵ 7.5-22.00

6. A chalcogenide glass composition according to claim 2, wherein said composition contains 58.00-75.00 moI% of sulfur.

7. A chalcogenide glass composition according to claim 2 or claim 6, wherein said composition contains 0-20.00 mol% Ga.

8. A chalcogenide glass composition according to any one of claims 2, 6, or 7, wherein a portion of the gallium is replaced by indium. 9. A chalcogenide glass composition according to any one of claims 2 and 6 to 8, wherein said composition contains 35.00 - 40.00 moi As.

10. A chalcogenide glass composition according to any one of claims 2 and 6 to 9, wherein a portion of the arsenic is replaced by antimony. 1 . A chalcogenide glass composition according to any one of claims 2 and 6 to 10, wherein said composition contains 0-25.00 mol Ge.

12. A chalcogenide glass composition according to any one of claims 2 and 6 to 1 1 , wherein said composition contains 0-10.00 mol% Hal.

13. A chalcogenide glass composition according to claim 3, wherein said composition contains 30.00-65.00 mol% of selenium.

14. A chalcogenide glass composition according to claim 3 or claim 13, wherein said composition contains 15-25.00 mol% Ge.

15. A chalcogenide glass composition according to any one of claims 3, 13, or 14, wherein said composition contains 5-22.00 mol% Ga.

16. A chalcogenide glass composition according to any one of claims 3 and 13 to 1 5, wherein a portion of the gallium is replaced by indium.

17. A chalcogenide glass compositio according to any one of claims 3 and 13 to 16, wherein said composition contains contain 5-15.00 mol% Hal¹.

1 8. In a night vision device comprising an infrared optical element, an image enhancer or intensifier, and a phosphor or fluorescent display, the improvement wherein said infrared optical element comprises a lens made of from a chalcogenide glass composition according to any one of claims 1 to 17.

19. In an infrared or thermal imaging system comprising an infrared optical element, a plurality of thermal sensors for detecting the infrared light and converting it into electrical signals, and a signal-processing unit for converting the electrical signals into a visual image, the improvement wherein said infrared optical element comprises a lens made of from a chalcogenide glass composition according to any one of claims 1 to 17.

20. A doublet lens comprising an infrared lens paired with a corrective lens wherein said infrared lens is made of ZnSe, ZnS, Ge, GaAs, BaF , or chalcogenide glass, and said corrective lens made from a. chalcogenide glass composition according to any one of claims 1 to 17.

21. Aii infrared lens system comprising a first infrared lens and a focal corrector doublet lens comprising a pair of corrective lenses, wherein said first infrared lens is made of ZnSe, ZnS, Ge, GaAs, BaF₂, or chalcogenide glass, one of said pair of corrective lenses has a positive power and the other has a negative power, and at least one of said pair of coiTeciive lens is made from a chalcogenide glass composition according to any one of claims 1 to 17.

22. A. sulfur-containing chalcogenide glass compositio according to any one of claims 1, 2, 4, and 6-12, wherein said glass composition optionally further contains Se, and the ratio of Se/S is up tol .O.

23. A selenium-containing chalcogenide glass composition according to any one of claims 1, 3, 5, and 13-17, wherein said glass composition optionally further contains S, and the ratio of S/Se is up tol .O.

24. A chalcogenide glass composition according to claim 22 or 23. wherein the sum of the amount of S plus the amount of Se is greater than the sum of 2 times the amount of Ge plus 1.5 times the amount of Ga,

25. A chalcogenide glass composition comprising (based on mol %):

Component Mole %

PbHafe 10.00-50.00

GeSe₂ 0-60.00

Sb₂Se.3 0-50.0

Sum of GeSe₂ and Sb₂Se3 50.00-90.00

0-15.00

(added in the form of R1HaI)

M 0-5.00

(added in the form of M Hal₂)

M² 0-30.00

(added in the form of M²HaI₂)

Ln 0-2.00

(added in the form of LnHal₃) Sum of R³, R², M¹ , M², and Ln Q~ 15,00

(added in the forms of R^'Ha ,

R^"HaL M^!Hal₂, M²Hal_2? and

LnHals)

wherein

S lai ^::: fluoride, chloride, bromide, and/or iodide, (preferably Br and/or I, with a Br/Ϊ ratio of 0-OJ),

R^! = Li, Na, K, Rb, and/or Cs,

R^-i = Ag and/or Cu,

M¹ = Mg, Ca, Sr, and/or Ba,

M^{2 ::::} Zn, Cd, and/or Hg

Ln ^::: La, Ce, Pr, Nd, Pm, Sm Eu, CM, Tb, Dy, Ho, Er, I^'m, Ty, Lu, Y, and